Table of contents

1. Front Cover
2. Table of contents
3. Science and technology for the conservation of cultural heritage:A European view
4. ACKNOWLEDGMENTS
5. Chapter 1: monitoring of cultural heritag
6. Chapter 2: Environmental risks assessment and preventive conservation strategy for the Pórtico de la Gloria, Santiago de Compostela Cathedral
7. Chapter 3: Basic descriptive statistical methods for monitoring and evaluation of microclimates in Cultural Heritage
8. Chapter 4: Evaluation of environmental conditions of the Museo del Ejército(Toledo, Spain) by means of Sol-Gel optical sensors
9. Chapter 5: Microclimatic assessment and modelling for salt crystallization control in the Crypt of the Duomo of Lecce (South Italy)
10. Chapter 6: Microclimatic studies in Paranhos water galleries, Porto (Portugal)
11. Chapter 7: Bio-susceptibility of thermal insulation systems usedfor historical buildings
12. Chapter 8: Biological crusts contribute to the protection of NeolithicHeritage in the Mediterranean region
13. Chapter 9: The influence of substrate texture on early biological colonization
14. Chapter 10: A methodological approach to evaluate shelter effectiveness for the conservation of archaeological sites
15. Chapter 11: Risks of atmospheric aerosol for cultural heritage assetsin Granada (Spain)
16. Chapter 12: Microclimatic and Ground-Penetrating Radar surveys for damagediagnosis. The case of the Crypt of the Duomo of Lecce (Italy)
17. Chapter 13: Entry and dispersion of microorganisms inside Altamira Cave:New evidences from aerobiological and atmospheric gases surveys
18. Chapter 14: Canonical Biplot as tool to detect microclimates in the inner and outer parts of Salamanca Cathedrals
19. Chapter 15: Polar compounds in diesel soot and historic monument surfaces
20. Chapter 16: The Seville Cathedral altarpiece: A microbiological and chemical survey of the dust
21. Chapter 17: Decay assessment through wireless sensor networks implementation for architectural heritage conservation
22. Chapter 18: Vivianite: A historic blue pigment and its degradation under scrutiny
23. Chapter 19: Stabilization works at Olvés Church (Zaragoza-Spain)
24. Chapter 20: Detrimental rock black fungi and biocides: A study on the Monumental Cemetery of Cagliari
25. Chapter 21: Microbiological and molecular investigation in the Capuchin Catacombs of Palermo, Italy: Microbial deterioration risk
26. Chapter 22: Physical and aesthetical decay of built heritage from biological films developed on joint mortars
27. Chapter 23: Indoor pollution and metal corrosion by organic acids: Case study of the Oteiza Museum (Spain)
28. Chapter 24: The degradation of cellulose acetate: Advanced analytical tools for non-destructive study of design objects
29. Chapter 25: Characterization of decay products and building materials on the ancient wall of Vitoria-Gasteiz using micro analytica
30. Chapter 26: Alterations of materials at the façades of the church of San Pedro de Mezonzo (A Coruña, NW Spain)
31. Chapter 27: Decay of building materials in the Circular Mausoleum, Necropolis of Carmona, Spain
32. Chapter 28: The erosion of granite surfaces: The Cathedral of Évora as example
33. Chapter 29: Study of the long term stability of an industrial polyamide from a contemporary artwork
34. Chapter 30: Study of the corrosion products of the lead blocks from the historical organ Jean Pierre Cavaillé of Vinça, France
35. Chapter 31: Causes of decay of Eduardo Chillida’s Monument to Tolerance in Seville (Spain)
36. Chapter 32: Analysis of heat effects due to fires on calcareous stones
37. Chapter 33: Degradation of plastic artifacts: Case study of a “drafting machine” made of different cellulosic plastics
38. Chapter 34: Evaluation of mural paintings biodeterioration by oxalate formation
39. Chapter 35: Study of the influence of black dyes in the physico-mechanical behaviour of silk fabrics
40. Chapter 36: VARIM 2.0: Non invasive NIR hyperspectral imaging for analysis of cultural beings
41. Chapter 37: Non-invasive recording technologies for the study and conservation of prehistoric rock art: The Dolmen of Dombate
42. Chapter 38: Modern methods of documentation for conservation— digital mapping and automated 3D object documentation in software me
43. Chapter 39: Innovative testing solutions for safeguarding architectural heritage
44. Chapter 40: Assessment of laser treatment on dolostones colonized by microorganisms and lichens
45. Chapter 41: Effect of wavelength and pulse duration on laser cleaning of paints
46. Chapter 42: Pigments and painting preparations of Gonzalo Bilbao analysed by non-destructive XRF technique
47. Chapter 43: A novel approach for micro FTIR reflection absorption analysis of artworks’ surface
48. Chapter 44: Methodology for the study of the walls of the Patio de Santo Tomás, University of Alcalá
49. Chapter 45: The altarpiece of the church of Freixo de Espada-à-Cinta: A study on its artistic materiality
50. Chapter 46: Optically Stimulated Luminescence dating of Roman mortars in Braga (Portugal)
51. Chapter 47: Analytical studies of 19th century photographs by non-destructive techniques
52. Chapter 48: Rheological analysis of some historical and commercial binders labelled as thixotropic in oil painting references
53. Chapter 49: Bricks and mortars from the “Patio de Santo Tomás”, Alcalá University (Madrid, Spain): A combined study of fabric char
54. Chapter 50: Study of alterations on Roman masonry in the Tower of Hercules
55. Chapter 51: The application of non invasive geophysical techniques for the diagnosis and conservation of stone cultural heritage:
56. Chapter 52: Conservation of historic book bindings by means of facsimile reproduction: The Torres Notarial Register (1382–1400) in
57. Chapter 53: Hybrid sol-gel based protective coatings for historical window glasses
58. Chapter 54: Mineralogical and textural considerations in the assessment of aesthetic changes in dolostones by effect of treatments
59. Chapter 55: The Arabic Manuscripts Collection of the School of Arabic Studies-CSIC, Granada: Characterisation of decorative covers
60. Chapter 56: Low-cost airborne ultrasounds scan for Cultural Heritage
61. Chapter 57: Molecular approach for the characterization of ancient/degraded Cyperus sp. specimens
62. Chapter 58: Roman glasses from Augusta Emerita: Study of degradation pathologies using LIBS
63. Chapter 59: Evaluation of the reinforcing action of consolidating treatments applied on cement mortars using the micro-sandblastin
64. Chapter 60: Cachão da Rapa prehistoric rock art paintings revisited: Digital image analysis approach for the assessment of Santos
65. Chapter 61: Benefits of applying spectrometric techniques and chemometric methods to identify interaction between historic paintin
66. Chapter 62: Study of degree of alteration of enamels using Micro-ATR-FTIR and SEM-EDS
67. Chapter 63: Non-chemical methods to control pests in museums: An overview
68. Chapter 64: Novel proteases from marine organisms with potential interest in restoration procedure
69. Chapter 65: Nanostructured materials for stone consolidation in the Temple Valley of Agrigento: In situ evaluation of their effect
70. Chapter 66: Thermodynamic modeling of sulfate-resistant cements with addition of barium compounds
71. Chapter 67: Semi-interpenetrating p(HEMA)/PVP hydrogels for the cleaning of water-sensitive painted artifacts: Assessment on relea
72. Chapter 68: Application of new organic-inorganic materials as consolidants for deteriorated plasters
73. Chapter 69: Consolidation treatments for conservation of concrete sculptures
74. Chapter 70: Thaumasite formation in hydraulic mortars: Thermodynamic studies
75. Chapter 71: Permanent anti-graffiti for artificial construction materials: Lime mortar and brick
76. Chapter 72: Nanostructured products for the conservation of the wooden supports: Evaluation of their effectiveness and durability
77. Chapter 73: Design of new gypsum-lime based mortars applied on the restoration of Mudejar heritage from Aragon (Spain)
78. Chapter 74: Old materials, new solutions
79. Chapter 75: Application of the double layer system as preventive method in the moulding process of sculptures and ornaments
80. Chapter 76: Effectiveness of a new nanostructured consolidant on the biocalcarenite from Agrigento Temples Valley
81. Chapter 77: Technical studies for the restoration of the Immaculate Conception monument, Seville
82. Chapter 78: Materials made from polyolefins used in tasks of preventive conservation: A comparative study of their long-term behav
83. Chapter 79: Critical and technical aspects for safeguarding, enhancing and the recovery of local architectural heritage: An emblem
84. Chapter 80: The protection of the baserri as a system for organising rural landscapes in the context of the urban sprawl processes
85. Chapter 81: A petrological approach to the study of grinding mortars from the Roman gold mines of “Pino del Oro” (Zamora, Spain)
86. Chapter 82: Origin and evolution of the agricultural landscape in Santiago de Compostela from the properties of a polycyclic terra
87. Chapter 83: Possibilities of LASER conservation of metal objects from archaeological context
88. Chapter 84: Geomatics applied to the monitoring of the damage and stability of the heritage
89. Chapter 85: Contribution of GIS and spatial analysis tools in the characterization of surface damage to paintings
90. Chapter 86: Predictive model for the useful lifetime of a set of buildings of the Archdiocese of Seville
91. Chapter 87: Risk analysis in Historical cities: The cases of Carmona and Estepa (Seville, Spain)
92. Chapter 88: The MHS system as an active tool for the preventive conservation of Cultural Heritage
93. Chapter 89: Significance and social value of Cultural Heritage: Analyzing the fractures of Heritage
94. Chapter 90: CSI: Sittingbourne: Conservation science investigations in a town center shopping mall
95. Chapter 91: Neomudéjar Architecture in Seville: Urban and social background, interventions in the Patio House (1880–1930)
96. Chapter 92: Iron Age goldwork as Cultural Heritage: Building strategies for its research, conservation and social valuation in NW
97. Chapter 93: Las Médulas: The social appraisal of a cultural landscape
98. Chapter 94: Documenting the architectonic heritage: The best way of preserving it
99. Chapter 95: Quantitative research underpins heritage management: Preserving ferrous metals
100. Chapter 96: New protocols for built heritage protection in the Basque Country: Towards an automatic analysis tool for built herita
101. Chapter 97: Review of restoration interventions: Effects on the Roman archaeological site of Merida (Spain)
102. Back Cover